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A re‐assessment of sucrose signaling involved in cluster‐root formation and function in phosphate‐deficient white lupin ( Lupinus albus )
Author(s) -
Wang Zhengrui,
Shen Jianbo,
Ludewig Uwe,
Neumann Günter
Publication year - 2015
Publication title -
physiologia plantarum
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 1.351
H-Index - 146
eISSN - 1399-3054
pISSN - 0031-9317
DOI - 10.1111/ppl.12311
Subject(s) - sucrose , lupinus , fructose , axenic , carbohydrate , biology , botany , phosphate , chemistry , biochemistry , genetics , bacteria
Apart from substrate functions, a signaling role of sucrose in root growth regulation is well established. This raised the question whether sucrose signals might also be involved in formation of cluster‐roots ( CRs ) under phosphate (Pi) limitation, mediating exudation of phosphorus (P)‐mobilizing root exudates, e.g. in Lupinus albus and members of the Proteaceae. Earlier studies demonstrated that CR formation in L. albus was mimicked to some extent by external application of high sucrose concentrations (25 m M ) in the presence of extremely high P supply (1–10 m M ), usually suppressing CR formation. In this study, we re‐addressed this question using an axenic hydroponic culture system with normal P supply (0.1 m M ) and a range of sucrose applications (0.25–25 m M ). The 2.5 m M sucrose concentration was comparable with internal sucrose levels in the zone of CR initiation in first‐order laterals of P‐deficient plants (3.4 m M ) and induced the same CR morphology. Similar to earlier studies, high sucrose concentrations (25 m M ) resulted in root thickening and inhibition of root elongation, associated with a 10‐fold increase of the internal sucrose level. The sucrose analog palatinose and a combination of glucose/fructose failed to stimulate CR formation under P‐sufficient conditions, demonstrating a signal function of sucrose and excluding osmotic or carbon source effects. In contrast to earlier findings, sucrose was able to induce CR formation but had no effect on CR functioning with respect to citrate exudation, in vitro activity and expression of genes encoding phosphoenolpyruvate carboxylase, secretory acid phosphatase and MATE transporters, mediating P‐mobilizing functions of CRs .